Hani Belhadj Et Al. 2014 (BMFH)
-
Upload
hanibelhadj -
Category
Documents
-
view
225 -
download
0
Transcript of Hani Belhadj Et Al. 2014 (BMFH)
-
7/27/2019 Hani Belhadj Et Al. 2014 (BMFH)
1/13
Phenotypic and Genotypic Characterization of SomeLactic Acid Bacteria Isolated from Bee Pollen:A Preliminary Study
Hani BELHADJ1* Daoud HARZALLAH1, Dalila BOUAMRA2, Seddik KHENNOUF2, Saliha DAHAMNA2and
Mouloud GHADBANE1, 3
1Laboratory of Applied Microbiology, Department of Microbiology, Faculty of Natural and Life Sciences, University Stif 1 Ferhat
Abbas, 19000 Stif, Algeria2Laboratory of Phytotherapy Applied to Chronic Diseases, Faculty of Natural and life Sciences, University Stif 1 Ferhat Abbas,
19000 Stif, Algeria3Laboratory of Plant Biotechnology, Department of Natural and Life Sciences, Sciences Faculty, University of Msila, PO Box 166
Msila, Algeria
Received March 15, 2013; Accepted August 20, 2013
In the present ork, ve hundred and sixty-seven isolates of lactic acid bacteria ere recovered from ra bee pollengrains. All isolates ere screened for their antagonistic activity against both Gram-positive and Gram-negative
pathogenic bacteria. Neutralized supernatants of 54 lactic acid bacteria (LAB) cultures from 216 active isolates
inhibited the groth of indicator bacteria. They ere phenotypically characterized, based on the fermentation of 39
carbohydrates. Using the simple matching coefcient and uneighted pair group algorithm ith arithmetic averages
(UPGMA), seven clusters ith other to members ere dened at the 79% similarity level. The folloing species
ere characterized: Lactobacillus plantarum, Lactobacillus fermentum, Lactococcus lactis, Pediococcus acidilactici,
Pediococcus pentosaceus, and unidentied lactobacilli. Phenotypic characteristics of major and minor clusters ere
also identied. Partial sequencing of the 16S rRNA gene of representative isolates from each cluster as performed,
and ten strains ere assigned to seven species:Lactobacillus plantarum,Lactobacillus fermentum,Lactococcus lactis,
Lactobacillus ingluviei,Pediococcus pentosaceus,Lactobacillus acidipiscisand Weissella cibaria. The molecular method
used failed to determine the exact taxonomic status of BH0900 and AH3133.
Key ords: lactic acid bacteria, numerical clustering, pollen, functional foods, UPGMA, 16S rRNA gene sequencing
Beehive products (honey, pollen, propolis and royal
jelly) are natural functional foods that have gained
increased attention in society [1]. Pollen, the male
gametophyte of owering plants, is a high-energymaterial collected by honeybees and other insects and
stored as a food reserve. Pollen has been used traditionally
by humans as a supplementary food and in alternative
medical treatments. It has been used medically in
prostatitis, bleeding stomach ulcers and some infectious
diseases [2].Because of its complex content, bee-pollen has a veryimportant nutritional value in the human diet [3]. Since the
middle of the last century, the bee-pollen microora hasbeen investigated [410]. However, little is known about
the occurrence of lactic acid bacteria (LAB), and the roles
they play, in pollens. Only a few reports are available in theliterature considering this eld. Occurrence of lactobacilliin pollens was reviewed by Gilliam [7]. In another study,Vsquez and Olofsson [11] identied lactobacilli isolatedfrom pollen grains. These isolates were identied basedon PCR and 16S rRNA gene sequencing. Other LAB
representative genera (Lactococcus, Lactobacillus,
Pediococcus, Enterococcus and Leuconostoc) were
recovered and identied based on phenotypic traits [4].In the latter investigation, in vitro studies indicated thatseveral strains inhibit Gram-positive and Gram-negative
pathogenic bacteria. Additionally, several members of
LAB are known to produce antibacterial substances suchas organic acids and bacteriocins. Antagonism towardsundesirable microorganisms is an important criterion for
LAB being used as bio-preservations or biocontrol agents.It seems that pollens are a suitable ecological niche for
various microorganisms and an important source for the
isolation of new strains belonging to the LAB group with
*Corresponding author. Mailing address: Hani Belhadj, Labora-tory of Applied Microbiology, Department of Microbiology,
Faculty of Natural and Life Sciences, University Stif 1 Ferhat
Abbas, 19000 Stif, Algeria. Phone:+213 775-159-039. E-mail:[email protected]
Full Paper Bioscience of Microbiota, Food and Health Vol. 33 (1), 1123, 2014
-
7/27/2019 Hani Belhadj Et Al. 2014 (BMFH)
2/13
H. BELHADJ, et al.12
antagonistic activity against harmful bacteria. Species or
subspecies identication of such strains is recommended.In fact, physiological and biochemical criteria used for
LAB identication are often ambiguous because most ofthe bacteria have very similar nutritional requirements and
grow under similar environmental conditions. Therefore,clear identication to the species level by simple
phenotypic tests may sometimes be difcult [12]. Indeed,additional molecular-based characterization approachessuch as 16S rRNA gene sequencing, 16S-ARDRA, PFGEand other methods are used for assignment of a given
LAB strain to its taxonomic status.
The present work describes isolation and phenotype-based numerical clustering of LAB isolated from pollen
grains collected in some Algerian areas; 16S rRNA
gene sequencing-based characterization of selectedstrains was investigated. Also, their antagonistic activityagainst Gram-positive and Gram-negative bacteria wasevaluated.
EXPERIMENTAL
Isolation of LAB from pollen
Previous studies [4] indicate that pollen samples takenfrom pollen traps are highly contaminated, especially by
enterococci. Furthermore, dilution-based LAB isolationis not a sufcient manner for the recovery of these
bacteria from pollen grains, and full negative results are
unavoidable with this method. Hence, a simple techniqueis used for the efcient isolation of LAB. In the eldduring owering seasons, honey bee foragers are kinched(catched) by a sterile stainless steel or plastic forceps.
The pollen pellets (60 samples from 10 clean regions;
six subsamples from each sampling site; in Bordj Bou
Arreridj and Stif) are then collected by a humidiedsterile cotton swab by gently touching the pollen pelletsattached to the posterior legs of the bee. At this time,
we can discuss the facts regarding bee-collected pollenfrom a microbiological point of view. The swabs weretransported to the laboratory at low temperature (5C)and analyzed or further maintained with refrigerationuntil use. Because LAB isolation is enrichment-basedmethod, the quantity of pollen recovered is not important.
Each swab was then introduced into a capped glasstube containing 15 mL Elliker broth pH 6.5 [13], andincubated anaerobically at 30C for at least two days.Afterwards, serial dilutions were prepared from each tubein peptone water (0.1% peptone and 0.1% of Tween 80),and from the appropriate dilution, aliquots (100 L) werespread and cultured on the following media: M17 agar(Fluka) incubated for 72 hr at 30C for lactococci andstreptococci, LBS agar [14] after anaerobic incubation
(BBL GasPack System) at 30C for 72 hr for lactobacilli,Glucose Yeast Extract Agar [15] incubated at 30Cfor 48 hr to isolate leuconostocs and pediococci, and
D-MRS agar [16] incubated at 25C for 72 hr to isolatecarnobacteria. Enterococci were treated in a separatestudy. From each culture, 1030 colonies were randomly
picked up and further puried on MRS agar (pH 6.5).Pure isolates were maintained at 20C in MRS brothcontaining glycerol (20%, v/v nal concentration).
Screening for antagonistic activity
For detection of antagonistic activity, an agar welldiffusion assay was used according to Schillingerand Lucke [17]. Bacterial species used as indicator
Table 1. Indicator bacteria used and their growth conditions
Indicator species Strain no. OriginGrowthmedium
Incubation
conditions
Gram-positive bacteria Bacillus subtilis 20302 CLAMa BHIc 37C
Enterococcus faecium H421 CLAM MRSd
30C Listeria innocua 3030 CLAM BHI 37C Staphylococcus aureus 25923 ATCCb BHI 37C
Gram-negative bacteria Escherichia coli 25922 ATCC BHI 37C Salmonella typhimurium 1717 CLAM BHI 37C Pseudomonas aeruginosa 27853 ATCC BHI 37C Shigellasp. 96415 CLAM BHI 37C
aCollection of Laboratory for Applied MicrobiologybAmerican Type Culture CollectioncBrain heart infusion brothdDe Man, Rogosa and Sharpe broth
-
7/27/2019 Hani Belhadj Et Al. 2014 (BMFH)
3/13
POLLEN RESIDING ANTAGONISTIC LACTIC ACID BACTERIA 13
microorganisms were listed in Table 1. LAB isolateswere subcultured twice (1% inoculums, 24 hr, 30C)in 10 mL MRS broth (Fluka). The non-LAB weresubcultured twice (1% inoculum, 24 hr, 37C) in 10 mLBHI broth (Fluka) and kept frozen at 20C in BHI broth
supplemented with 20% glycerol. Cell-free supernatantsfrom LAB cultures were obtained by centrifuging thecultures (8,000 g/10 min at 4C), and then the pH of eachsupernatant was adjusted to 6.5 using 5N HCl followed
by ltration through a cellulose acetate lter with a poresize of 0.2 m. Before supernatant neutralization, an
antimicrobial assay was performed for all isolates. Allexperiments were performed in duplicate, and the resultswere displayed as the mean value of the experiments.Isolates showing antagonistic activity against one ormore indicator bacteria (with an inhibition zone diameterof more than 5 mm) were subjected for phenotypiccharacterization.
Phenotypic identication of bioactive isolates
Isolates exhibiting antagonistic activity were selectedon the basis of Gram staining, morphology, tetradformation and catalase activity. Catalase-negative andGram-positive rods and cocci were selected and screenedfor the production of CO2from glucose (in MRS broth,
containing Durham inverted tubes, without beef extractand citrate). Ability to grow at 10 and at 45C wasevaluated in MRS broth after incubation for 7 days and 48hr, respectively. Growth in MRS containing 6.5 or 18%
NaCl, as well as growth in MRS with pH 4.4 and 9.6, wasstudied. Acid production from carbohydrates (glycerol,
erythritol, D-arabinose, L-arabinose, ribose, D-xylose,L-xylose, adonitol, galactose, D-glucose, D-fructose,D-mannose, L-sorbose, rhamnose, dulcitol, inositol,mannitol, sorbitol, amygdalin, arbutin, salicin, cellobiose,
maltose, lactose, melibiose, saccharose, trehalose,
inulin, melezitose, D-rafnose, starch, glycogen,xylitol, gentiobiose, D-lyxose, D-tagatose, D-arabitol,L-arabitol, and gluconate) was evaluated by miniaturizedassay in 96-well at-bottom microtiter plates [18]. Sterile
carbohydrate solutions (Institut Pasteur, France) wereadded to the basal medium (MRS without glucose andmeat extract and with 0.16 g/L bromocresol purple, pH7.0) at a nal concentration of 1%. Cells were harvestedfrom overnight cultures by centrifugation (10,000 g,
5 min, 4C), washed twice in sterile phosphate buffer(pH 7.0) and suspended in sterile saline (0.85% NaCl).This suspension was used to inoculate sterile microtiter
plates (96 at-bottom wells), which were incubated inanaerobiosis for 7 days at 30C. Esculin hydrolysis wasassessed by adding 2 g/L esculin (Sigma) and 5 g/L ferric
ammonium citrate (Sigma) to the basal medium.
Fermentation of each of the 39 carbohydrates wasinterpreted as follows: positive (+), complete changeto yellow; weakly positive (w), change to green; andnegative (-), no change at all. Esculin hydrolysis (revealed
by a change to a darker color) was interpreted as positive(+), while no change was negative (-). Strains were testedin duplicate to determine the test reproducibility.
Genotypic identication of selected LAB strains
Sample preparation prior to PCR amplication
As described by Rodas et al. [19], selected LAB
isolates (10 strains displaying a remarkable assimilatorypattern) were grown in MRS agar at 30C for 2 days. Onesingle colony was picked up from plates and suspendedin 20 L of sterile distilled water. These suspensionswere used for PCR reactions without further processing.
Amplication and sequencing of 16S rRNA gene
The protocol of Rodas et al. [19] was used for16S rRNA gene amplication using primers pA(8-AGAGTTTGATCCTGGCTCAG-28) and pH(1542-AAGAGGTGATCCAGCCGCA-1522) [20].DNA amplication was carried out in a 50 L PCRmixture containing 200 M dNTP, 1 M of each
primer, 20 mM Tris-HCl (pH 8.4), 50 mM KCl, 2 mMMgCl2, 6 U of Taq DNA polymerase and 1 L of the
cell suspension. Each PCR cycle consisted of an initialdenaturation time of 5 min at 94C followed by 35 cyclesof amplication comprising a denaturation step for 30sec at 94C, annealing at 56C for 30 sec, and extensionat 72C for 1 min. Reactions were completed with 5 minelongation at 72C followed by cooling to 10C. PCR
products were resolved by electrophoresis at a constantvoltage (200 V) in 1.2% (w/v) agarose in 0.5 x TBE(45 mM Tris-HCl, 45 mM boric acid and 1 mM EDTA
pH 8.0), gels were stained with ethidium bromide (0.5g/mL). Amplication products were puried using aPCR purication kit (Qiagen, Germany) and sequencedusing the BigDye Terminator v3.1 Cycle Sequencing
Kit and an automated DNA sequencer (ABI Prism
3100 Avant Genetic Analyzer, Applied Biosystems). Thenucleotide sequences of the 16S rRNA gene of all theisolates were analyzed and determined by the BLAST
program on the NCBI website (http://www.ncbi.nlm.nih.gov/). The alignments were analyzed to construct a
phylogenetic tree and to compare similarities among the
sequences by the neighbor-joining method [21] usingMEGA software version 4.0. Bootstrap analysis was usedto evaluate the tree topology of the data by performing
1,000 resamplings. The sequences were deposited in theGenBank database using the web-based data submission
-
7/27/2019 Hani Belhadj Et Al. 2014 (BMFH)
4/13
H. BELHADJ, et al.14
tool Sequin (http://www.ncbi.nlm.nih.gov/Sequin).Statistical analysis
Hierarchical cluster analysis was carried out withStatistica 6 software (Statsoft Italia, Padua, Italy). TheEuclidean distance, unweighted pair group method witharithmetic mean (UPGMA) and an index of similaritywere used for the analysis of carbohydrate fermentation.A two-way ANOVA test was used for comparingantimicrobial activity of LAB.
RESULTS
Isolation and antagonism among LAB strains
From the ten sampling zones, distributed across twoprovinces, six samples were collected from each zone.
However, a total of 567 isolates were recovered frompollen grains. Growth of yeasts and molds on isolationagar media was observed and conrmed by microscopicexamination. Also, catalase-positive bacterial colonieswere encountered. Presumptive LAB cells were carefullyselected based on catalase reaction, cell shape, motility
and Gram staining. All Gram-positive, catalase-negativecocci and rods were puried on suitable agar media tohomogeneity. The 567 pure LAB strains were screenedfor their antagonistic activity by agar well diffusionassay against eight undesirable bacteria belonging to
Gram-positive and Gram-negative ranks (Staphylococcusaureus ATCC 25923, Bacillus subtilis CLAM 20302,
Enterococcus faecium CLAM H421, Listeria innocua
CLAM 3030, Shigellasp. CLAM 96415,Escherichia coliATCC 25922, Salmonella typhimurium CLAM 1717,and Pseudomonas aeruginosa ATCC 27853). After arandom screening process, using neutralized supernatant
cultures, 216 stains found to potentially inhibit at least
one indicator bacteria, whereas 351 were not. Statisticalanalysis indicated that total percentage of potent strains
(40.74 6.31) was signicantly different (p=0.003 0.05), but is resulted from the indicator pathogenic bacteria themselves and extremely signicant differenceswere obtained (p
-
7/27/2019 Hani Belhadj Et Al. 2014 (BMFH)
6/13
H. BELHADJ, et al.16
inhibition diameters were between 10 and 33 mm (Fig.2B).
Clustering structure and analysis
Fifty-four bacteriocin-like producing isolates ofLAB obtained from different raw pollen samples were
characterized according to the method of Axelsson
[22], Bergeys Manual [23] and the prokaryotes [24].Preliminary, the diversity was studied based on a
phenotypic approach. Microplates containing 39 different
carbon sources and 10 other physiological traits were usedto determine the phenotypic proles of the 54 isolates of
Fig. 3. Dendrogram of combined phenotype proles of 54 potent antagonistic lactic acid bacteria isolates as determined bycarbohydrate fermentation and physiologic traits. Cluster analysis was carried out based on the simple matching coefcientand unweighted pair group algorithm with arithmetic averages (UPGMA). Codes of strains and clusters are indicated on theleft hand side of the gure.
-
7/27/2019 Hani Belhadj Et Al. 2014 (BMFH)
7/13
POLLEN RESIDING ANTAGONISTIC LACTIC ACID BACTERIA 17
LAB. The reproducibility of the fermentation tests was100%. The similarity coefcient cluster analysis resultedin ve major clusters (A, C, E, F and I, containing threeor more strains) dened at the 79.0% similarity level (Fig.3). The following four other minor clusters were dened
at the 79% similarity level (B, D, G and H, two 2-membercluster and two 1-member clusters).
Major clusters (A, C, E, F and I)
Cluster A), Lactobacillus plantarum, Lactobacillus
paraplantarum and Lactobacillus sp., comprised 18isolates from Bordj Bou Arreridj (BBA) (33.33%of the total isolates). The cluster contained eight
other Lactobacillus plantarum strains, one strain of
Lactobacillus paraplantarumand eightLactobacillussp.
strains. All strains were homofermentative, and 55.5% ofthe isolates in this cluster fermented L-arabinose. They didnot ferment xylose, adonitol, -methyl-xyloside, starch,arabitol and rhamnose. Alpha-methyl-D-mannoside wasvariously fermented. The same pattern was noted forgluconate, lactose and sorbitol. Members of this cluster
grew at 10 and 45C in the presence of 6.5% NaCl andat pH 4.4.
Cluster C), Lactobacillus plantarum, Lactococcus
lactissubsp. lactis, andLactobacillussp., contained three
Lactobacillus sp. members, one strain of Lactococcus
lactis subsp. lactis and two Lactobacillus plantarumstrains. All were homofermentative and grew well at10 and 45C, in the presence of 6.5% NaCl and underalkaline conditions (pH, 9.6). They all fermentedribose, hexoses, cellobiose, lactose, saccharose,
trehalose and B-gentiobiose, but they did not fermenterythritol, D-arabinose, xylose, adonitol, -methyl-xyloside, dulcitol, -methyl-D-glucoside, starch, xylitol,L-arabitol, D-lyxose, D-tagatose, D-fucose and L-fucose.They variously fermented L-arabinose, rhamnose,inositol, mannitol, sorbitol, -methyl-D-mannoside,melibiose, melezitose, D-rafnose, D-arabitol, gluconateand amygdalin.
Cluster E), Lactococcus lactis, Pediococcus
pentsaceusand Pediococcus acidilactici, contained vestrains of Lactococcus lactis subsp. lactis (AH3030,AH3031, AH3032, AH3333 and AH3533), six strainsof Pediococcus pentosaceus (AH3233, AH3233 L,
AH3233 M, AH3233 N, AH3233 and AH5655), andone strain of Pediococcus acidilactici (AH5255). Allstrains of this group were homofermenters and grew wellat 45C. The strains AH3030, AH3031, AH3032 andAH3333 did not grow at 10C or in the presence of 6.5%sodium chloride. They did not ferment D-arabinose,-methyl-xyloside, rhamnose, dulcitol, inositol,
sorbitol, -methyl-D-mannoside, -methyl-D-glucoside,melibiose and melezitose, but they did ferment ribose,
galactose, D-glucose, D-fructose, N-acetyl-glucosamine,amygdalin, arbutin, esculin, salicin and cellobiose.
Furthermore, L-arabinose, D-xylose, D-mannose,
mannitol, lactose, B-gentiobiose, maltose and saccharosewere variously fermented. In addition, only the strain,
Lactococcus lactisAH3533, was able to ferment starchand gluconate.
Cluster F), this cluster contained four strains of
Lactobacillus sp., BH1611, BH1711, BH181 andBH1911. They grew at pH 4.4, at 10 and 45C and inthe presence of 6.5% sodium chloride, but they didnot grow at pH 9.6. They fermented ribose, xylose,hexoses, -methyl-D-mannoside, N-acetyl-glucosamine,amygdalin, arbutin, salicin, cellobiose, maltose, lactose,
melibiose, saccharose, trehalose and D-rafnose. Theydid not ferment melezitose, gluconate, inositol, mannitol,
rhamnose, D-arabinose and -methyl-xyloside.Cluster I), contained strains of Pediococcus
pentosaceus and Lactobacillus plantarum. Members of
this cluster (seven strains of Pediococcus pentosaceus
and one strain Lactobacillus plantarum BH1010) werehomofermenters. All strains were able to grew at 10and 45C, at pH 4.4 and in the presence of 6.5% NaCl.However, D-arabinose, L-arabinose, -methyl-xyloside,galactose, D-glucose, D-fructose, -methyl-D-glucoside,
N-acetyl glucosamine, amygdalin, arbutin, salicin,saccharose, xylitol and D-lyxose were fermented bymembers of this group. Adonitol was fermented by allstrains except Pediococcus pentosaceus AH7777 and
Lactobacillus plantarumBH1010. In addition, none of the
strains fermented ribose, xylose, D-mannose, L-sorbose,rhamnose, dulcitol, sorbitol, -methyl-D-mannoside,trehalose, D-rafnose, starch, gentiobiose, gluconate andD-arabitol. Melezitose, inositol, mannitol, maltose andlactose were fermented only byLactobacillus plantarumBH1010.
Minor clusters and stragglers (B, D, G and H)
Cluster B contained one strain of Lactobacillusfermentum; cluster D contained two strains,Lactobacillusfermentum and Lactobacillus sp. One strain identiedas Lactobacillus plantarum was assigned to cluster G.However, two other strains,L. fermentum, were groupedin cluster H. All strains were heterofermenters and growat 45C and in the presence of 6.5% of sodium chloridewith the exception of strain BH2422. Members of clusterH were able to grow at pH 9.6 compared with strainsof the other clusters. None of the strains fermented
erythritol, adonitol, -methyl-xyloside, D-lyxose,
-
7/27/2019 Hani Belhadj Et Al. 2014 (BMFH)
8/13
H. BELHADJ, et al.18
D-tagatose, D-fucose, L-arabitol and 2-keto-gluconate.However, strain BH2422 (cluster H) was also unableto ferment D-arabinose. Table 2highlights the differentcarbohydrates variously fermented by members of the
clusters obtained at the similarity level of 79% (A-I).
Genotypic characterization of selected LAB strains
Sequences of the 16S rRNA gene (approximately
1,500 bp) of ten LAB isolates, BH0900, BH1511,AH3133, BH0500, AH5655, AH3030, BH1711,BH0600, BH2422, and AH3433A, were determined.The 16S rRNA nucleotide sequences of the isolates
were aligned with homologous regions from variousLAB, and a phylogenetic tree was constructed by the
neighbor-joining method (Fig. 4). The BLAST analysisof 16S rRNA gene sequences of the selected strainsshowed alignments of these sequences with reported 16SrRNA genes in the gene bank. The nucleotide sequenceswere deposited in GenBank, and accession numbers forstrains BH0900, BH1511, AH3133, BH0500, AH5655,AH3030, BH1711, BH0600, BH2422 and AH3433A wereobtained (KF178303, KF178304, KF178305, KF178307,KF178308, KF178306, KF178310, KF178311,KF178312 and KF178309, respectively). However, the10 isolates were assigned to seven species,Lactobacillus
plantarum,L. fermentum,Lactococcus lactis,L. ingluviei,
Pediococcus pentosaceus, L. acidipiscis and Weissella
cibaria.
On the basis of phylogenetic data obtained, strain
BH0900 showed similarity (99%) with Lactobacillusplantarum WCFS1 (075041.1) and Lactobacilluspentosus124-2 (029133.1) as well as withLactobacillusparaplantarumDSM 10667 (025447.1) andLactobacillus
plantarumNRRL B-14768 (042394.1). However, strainBH1511 shares 99% similarity with Lactobacillus
fermentum IFO 3956 (075033.1) and 96% similaritywith Lactobacillus gastricus Kx156A7 (029084.1). Onthe other hand, strains AH3133 and AH3030 share 99%similarity with Lactococcus lactis subsp. lactis NCDO
604 (040955.1), Lactococcus lactis subsp. hordniaeNCDO 2181 (040956.1), Lactococcus lactis subsp.cremoris SK11 (074949.1), Lactococcus lactis subsp.cremoris NCDO 607 (040954.1) and 92% similaritywith Lactococcus plantarum DSM 20686 (044358.1).Furthermore, 99% similarity was shared between isolateBH0500 and Lactobacillus ingluviei KR3 (028810.1).In addition, two strains, AH5655 and AH3433A, wereclosely related (99%) toPediococcus pentosaceusDSM20336 (042058.1) and showed more than 98% similarity to
Pediococcus stilesiiLMG 23082 (042401.1). One strain,
Table 2. Phenotypic proles of the 54 potent LAB isolates as determined by carbohydrate fermentation
Cluster A18 isolates
Cluster B(BH1511)
Cluster C6 isolates
Cluster D(BH0400BH0500)
Cluster E 12isolates
Cluster F4 isolates
Cluster G(BH0600)
Cluster H(BH2722BH2422)
Cluster I8 isolates
D-Arabinose 5.5 0 0 0 0 0 0 50 100L-Arabinose 55.5 100 33.33 100 41.66 0 0 100 100Ribose 44.5 100 100 50 100 100 100 100 0Adonitol 0 0 0 0 0 0 0 0 75-M-xyloside 0 0 0 0 0 0 0 0 100D-Mannose 100 0 100 50 58.33 100 0 0 0Rhamnose 0 100 50 0 0 0 0 50 0Inositol 0 0 33.33 50 0 0 0 0 12.5Mannitol 100 100 83.33 50 41.66 0 0 50 12.5Sorbitol 50 100 83.33 0 0 100 0 50 0Alpha-M-D-mannoside 38.88 0 50 50 0 100 0 50 0-M-xyloside 0 0 16.2 50 0 50 0 0 100Cellobiose 100 0 100 50 100 100 0 50 25Maltose 100 100 100 50 91.66 100 100 100 12.5Lactose 10 100 100 100 41.66 100 100 100 12.5
Melibiose 100 100 66.7 50 0 100 100 100 87.5Saccharose 100 100 100 100 41.66 100 100 100 100
Trehalose 100 0 100 50 91.66 100 0 0 0Melezitose 100 100 83.33 50 0 0 0 50 12.5D-Rafnose 94.5 100 50 0 0 100 100 100 0Starch 0 0 0 0 8.33 75 0 50 0Gentiobiose 100 100 100 50 91.66 0 0 100 0
Numbers indicate the percent positive reaction of each test for the isolates of each cluster.
-
7/27/2019 Hani Belhadj Et Al. 2014 (BMFH)
9/13
POLLEN RESIDING ANTAGONISTIC LACTIC ACID BACTERIA 19
BH1711, displayed 98% similarity with Lactobacillusacidipiscis FS60-1 (024718.1). Strain BH0600,which was phenotypically identied as Lactobacillus
plantarum, was genotypically related (99%) toLactobacillus ingluvieiKR3 (028810.1). Finally, strainBH2422 was consideredLactobacillus fermentumbasedon phenotypic characterization; however, 16S rRNAgene sequence analysis revealed that this strain was
related to Weissellaand shared 99% sequence similaritywith Weissella cibariaII-I-59 (036924.1).
DISCUSSION
Isolation of LAB and antagonistic activity
The effectiveness of LAB is a strain-dependant aspect.This trait may be obtained by genetic manipulation or, as
is frequently the case, searching for new desirable strainsin natural niches. Plants, foods, fermented products,
animals and humans constitute natural ecological
systems and good sources for LAB. To the best of our
knowledge, antagonism of LAB against human bacterialgastrointestinal pathogens is the most important feature
for selecting such a strain designed for the human gut.
Here, we described isolation of LAB from rawpollen grains showing antimicrobial activity againstGram-positive and Gram-negative pathogenic bacteria.The 54 LAB effective strains were characterized by
means of phenotypic tests. The relationships amongthe phenotypically characterized strains of LAB weredetermined by cluster analysis. It is well known that
pollen grains are sterile before anther opening. Flowersand their constituents are parts of the plant phylloplane.
Stirling and Whittenburg [25] suggested that the LAB arenot usually part of the normal microora of the growing
plant and indicated the role of insects in the spread of
these organisms. LAB commonly found on fresh herbage
and in silage have been investigated [26, 27]. Nilssonand Nilsson [28] were found that the predominant
Fig. 4. Phylogenetic tree based on 16S rDNA sequence analysis, showing the phylogenetic placement of selected LAB strains isolatedfrom pollen grains. The tree was constructed by the neighbor-joining method, andPseudomonas syringaepv.syringaewas used as the
outgroup. Bootstrap values (expressed as percentages of 1000 replications) are shown at branch points.
-
7/27/2019 Hani Belhadj Et Al. 2014 (BMFH)
10/13
H. BELHADJ, et al.20
LAB during silage fermentation were streptococciand lactobacilli, with Lactobacillus plantarum thespecies most frequently recovered. Other studies
[29, 30] reported the occurrence of pediococci and
lactobacilli on leaving or decayed plants. Lactobacilli
commonly share the habitat phyllosphere with speciesof the genera Leuconostoc, Pediococcus and Weissella.
Species frequently recovered from the leaves include
L. plantarum,L. paracasei,L. fermentum,L. brevisand
L. buchneri [16], which is in line with our results. Partof the accumulated information about the occurrence
of lactobacilli (and other LAB members) on plants is
derived from microbiological studies of the fermentation
process. Thus, the microbial population upon initiation of
the process is known for several plants (grasses, cabbage,silage raw materials, carrots and beets, olives and fruitssuch as grapes and pears, etc.). But scarce information
about the occurrence of LAB on owers and pollens isavailable in the literature. Indeed, we report in this workthe occurrence of LAB in pollen grains and for the rsttime the isolation and characterization of several species
belonging to LAB. The results reported here indicate
that 54 isolates (25%) of the total antagonistic isolates(216 strains) inhibit indicator bacteria. Inhibition caused
by hydrogen peroxide and organic acids was ruled out,as the producer strains were cultured anaerobically andthe culture supernatant was neutralized (pH 6.5) beforeassaying the antimicrobial activity. This study indicates
that the compound inhibiting the microbial growth in theneutralized cell-free supernatant was not organic acid orhydrogen peroxide commonly produced by many LAB
[31].
As reported by Daeschel et al. [32], certain LAB
protect plants by producing antagonistic compounds
[12] contributing to inhibition of the plant pathogens
Xanthomonas campestris, Erwinia carotovora and
Pseudomonas syringae. Furthermore, LAB are wellknown for their antagonism towards other Gram-
positive bacteria, especially taxonomically related
species (Listeria spp., Bacillus spp. Micrococcus spp.,
etc.), and Gram-negative plant and animal pathogens,such asEscherichia coli, Salmonellaspp.,Helicobacterpylori and Pseudomonas aeruginosa. Contrary to whatis believed, that LAB are more potent in inhibiting
Gram-positive bacteria than Gram-negatives bacteria,which is claimed for the type of cell wall of the targetmicroorganism, this study reveals that Gram-negative
bacteria used in this study (E. coli, Salmonella
typhimurium, Pseudomonas aeruginosa, and Shigella
sp.) were susceptible to cell-free supernatants from testedLAB, especially the strains 9 (Pediococcus pentosaceus
AH3433E), 12 (Lactobacillus plantarum BH1010), 14(Lactobacillus plantarum BH0600), 16 (Lactobacillus
sp. BH1811), 19 (Pediococcus acidilacticiAH5255), 29(Lactobacillus plantarum BH0800), 39 (Lactobacillus
plantarum BH1411), 41 (Lactobacillus plantarum
BH0104) and 47 (Lactobacillus plantarum BH0102).These results are in accordance with earlier resultsreported by Trias et al. [33], who showed that most LABoriginating from fruits and vegetables displayed good
antagonistic activity against foodborne pathogens, such
as, Listeria monocytogenes, Salmonella typhimurium
andEscherichia coli. Several indicator strains displayed
different degrees of susceptibility towards antimicrobialcompounds from a given producer strain; for example,
strain 46 (Lactobacillus sp. BH2122) inhibits strongly
E. coli, Salmonella typhimuriumand moderately inhibits
Pseudomonas aeruginosabut is inactive towards Shigellasp. The indicator strainL. innocuawas used in this studyinstead ofL. monocytogenes, as the two microorganismsshow similar physiological properties with the differencethat the former does not belong to the pathogenic species
of Listeria. Moreover, some papers have reported a
greater sensitivity of L. monocytogenes towards someantibacterial compounds thanL. innocua[34, 35].
It is well known that the presence of lactobacilli isimportant for maintenance of the intestinal microbial
ecosystem [36]. They have been shown to possessinhibitory activity toward the growth of pathogenic
bacteria such as Listeria monocytogenes [37, 38],Escherichia coli and Salmonella spp. [39, 40]. This
inhibition could be due to the production of inhibitory
compounds such as organic acids, hydrogen peroxide, and
bacteriocins. Our results agreed with the latter statements;therefore, our isolates are strong candidates for clinical
use during gut treatment regimes. Furthermore, a major
advantage of using LAB as biocontrol agents is that they
are considered GRAS (generally recognized as safe) andusually comply with all recommendations for food anddrug products [41]. Moreover, LAB are natural colonizers
of fresh plant products and have been previously described
as good antagonists of several bacteria and fungi [42, 43].Siezen et al. [44] hypothesized that the fermentative
prole reects the original habitat and that lactoseutilization is less prevalent in plant isolates with respectto those from cheese and the human gastrointestinal
tract. Indeed, lactose was fermented by most isolates inthe present study, except isolates of Pediococcus from
clusters I and E and isolates of Lactobacillus sp. fromcluster A. The inability of plant-related LAB to fermentlactose was presumably due to the relatively recentacquisitions, via horizontal gene transfer and subsequent
-
7/27/2019 Hani Belhadj Et Al. 2014 (BMFH)
11/13
POLLEN RESIDING ANTAGONISTIC LACTIC ACID BACTERIA 21
natural selection, of lactose metabolic genes, which areoften plasmid encoded in dairy and human strains [45].Contrary to the ndings of Cagno et al. [46], who studied
Lactobacillus plantarum from vegetables and fruits, all
Lactobacillus plantarum isolates of this study used this
carbon source.
Overall, all isolates fermented maltose and cellobiose
except Pediococcus acidilactici AH5255 (cluster E)and Pediococcus pentosaceus AH3433, AH3433A,
AH3433B, AH3433C, AH3433D and AH3433E (clusterI). Strain AH7777 (Pediococcus pentosaceus; cluster I)fermented cellobiose but not maltose. Also, cellobiose
was not fermented byLactobacillus fermentumBH0400,Lactobacillus sp. BH0500 (cluster D), members ofcluster H (Lactobacillus fermentum BH2722, andBH2422) and members of clusters B and G. Arabinose,glucose, fructose, mannose, mannitol, B-gentiobiose,melezitose, melibiose, saccharose and trehalose werevariously fermented. These carbon sources correspond
mainly to those prevalent in the plant kingdom [47].Similar phenotypic proles were found forLactobacillus
plantarum isolated from Thai fermented fruits and
vegetables [45, 47, 48]. Glycosides such as amygdalinwere not used only by isolates of clusters H, D, B and C,salicin was not used only by eight isolates belonging tocluster A, (Lactobacillussp. BH0700, 0701, 0702, 0703,0704, 0705, 0706 and 0707). On the other hand, arbutinwas used by isolates of all clusters. These glycosides aretypically found in vegetables.
Starch is a reserve polysaccharide in pollen grains, and
starch-hydrolyzing strains belong to the clusters E, F, andH. According to the fermentation prole, it seems thatthe isolates assimilate variously a panel of carbohydrates
that reects their enzymatic and genetic potentials.Furthermore, these traits were shared with LAB of dairy oranimal origin. Based on the limited number of tests used,
phenotypic proles did not cluster the isolates accordingto the original habitat. This was probably because thestudied isolates were obtained from raw pollen sampleshaving a very similar chemical composition. It could
also have been because the pollen residing LAB were ofanimal as well as plant origin. Nevertheless, phenotypicproling was useful to understand the manifestations ofenvironmental adaptation, which will be reected in thetechnological processes.
From the different phenotypic clusters, ten selected
isolates (displaying a good assimilation activity) wereidentied by means of 16S rRNA gene sequencing. Itis well known that the species Lactobacillus plantarum,
Lactobacillus pentosusandLactobacillus paraplantarum
are genotypically closely related and show highly similar
phenotypes. In the present results, misidentication ofsome isolates to dened species was encountered. Moremolecular techniques should be used for determination
of the taxonomic status of these strains. The occurrence
of Weissella cibaria, Lactobacillus ingluviei and
Lactobacillus acidipiscisin pollen grains is in accordance
with the ubiquity of these bacteria in nature [24]. In fact,insects, honeybees, soil, water and animal and humanfeces are main microbial contamination sources of pollens
[4, 5]. From another point of view, misidentication ofsome isolates by phenotypic traits is probably due in
part to the limited characters used for this purpose, or
by the similarity of the metabolic patterns expressed by
the isolates, even if they belong to different genotypic
ranks. As reported elsewhere [19], physiological andbiochemical criteria used for LAB strain identicationare often ambiguous because most of the bacteria have
very similar nutritional requirements and grow undersimilar environmental conditions. Therefore, a clear
identication to species level by simple phenotypictests may be troublesome and inaccurate. Molecular
methods used for discrimination of LAB strains to genus
and species level are more efcient than phenotypicapproaches.
A preliminary study on LAB associated with pollenshaving remarkable antimicrobial activity is reportedhere. The uses of these strains for biocontrol or bio-
preservation purposes should be evaluated. Phenotypic
traits do not reveal the real taxonomic position of some
isolates; therefore, exploitation of other molecular
methods for exact identication of these bacteria is ofgreat scientic and practical interest. In addition, thesearch for new LAB exhibiting a wider spectrum ofantimicrobial activities from pollen grains that can be
used in human health, agriculture and the food industry
is of great importance. Furthermore, studies on other
biological and biotechnological criteria of these isolates
as well as their safety aspects are necessary. Finally, itseems that pollens and possibly other beehive products
are predominant sources for isolation of LAB with potent
applications.ACKNOwLEDGEMENTS
This work was supported by the Directorate General forScientic Research and Technological Development,Ministry of Higher Education and Scientic Research,Algeria. The authors wish to thank Dr. Arun Goyal(Professor and Former Head, Department of Biotechnology,
Indian Institute of Technology Guwahati, Guwahati-781039,Assam, India), for critical reading of the manuscript.
-
7/27/2019 Hani Belhadj Et Al. 2014 (BMFH)
12/13
H. BELHADJ, et al.22
REFERENCES
1. Viuda-Martos M, Ruiz-Navajas Y, Andez-LpzJF, Erez-Alvarez JAP. 2008. Functional properties ofhoney, propolis, and royal jelly. J Food Sci 73: R117R124. [Medline] [CrossRef]
2. Linskens HE, Jorde W. 1997. Pollen as food andmedicinea review. Econ Bot 51: 7886. [CrossRef]
3. Gergen I, Radu F, Bordean D, Isengard H. 2006.Determination of water content in bee pollen samplesby Karl Fischer titration. Food Contr 17: 176179.[CrossRef]
4. Belhadj H, Harzallah D, Khennouf S, Dahamna S,Bouharati S, Baghiani A. 2010. Isolation, identicationand antimicrobial activity of lactic acid bacteria from
Algerian honeybee collected pollen. Acta Hortic 854:5158.
5. Belhadj H, Bouamra D, Dahamna S, Harzallah D,Ghadbane M, Khennouf S. 2012. Microbiological
sanitary aspects of pollen. Adv Environ Biol 6: 14151420.
6. Chevtchik V. 1950. Mikrobiologie pylovho kvaslen,Publ Fac Sci. Univ Masaryk 323: 103130.
7. Gilliam M. 1979a. Microbiology of pollen and beebread: the yeasts. Apidologie (Celle) 10: 4353.[CrossRef]
8. Gilliam M. 1979b. Microbiology of pollen and beebread: the genus Bacillus. Apidologie (Celle) 10:
269274. [CrossRef] 9. Gilliam M, Prest DB, Lorenz BJ. 1989. Microbiology
of pollen and bee bread: taxonomy and enzymology of
molds. Apidology 20: 5368. [CrossRef]
10. Gilliam M, Roubik DW, Lorenz BJ. 1990.Microorganisms associated with pollen, honey, andbrood provisions in the nest of a stingless bee,Melipona
fasciata. Apidologie (Celle) 21: 8997. [CrossRef]11. Vsquez A, Olofsson TC. 2009. The lactic acid bacteria
involved in the production of bee pollen and bee bread.
J Apic Res 48: 189195. [CrossRef]12. Visser R, Holzapfel WH, Bezuidenhout JJ, Kotz
JM. 1986. Antagonism of lactic acid bacteria againstphytopathogenic bacteria. Appl Environ Microbiol 52:552555. [Medline]
13. Elliker PR, Anderson AW, Hannesson G. 1956. Anagar culture medium for lactic acid streptococci and
lactobacilli. J Dairy Sci 39: 16111612. [CrossRef]
14. Rogosa M, Wiseman RF, Mitchell JA, Disraily MN.
1953. Species differentiation of oral lactobacilli fromman. J Bacteriol 65: 681699. [Medline]
15. Holzapfel WH, Franz CMAP, Ludwig W, Back W,Dicks LMT. 2006. The Genera Pediococcus andTetragenococcus. Prokaryotes 4: 229266. [CrossRef]
16. Hammes WP, Hertel C. 2006. The generaLactobacillus
and Carnobacterium. In: The Prokaryotes 4: 320403.17. Schillinger U, Lucke FK. 1989. Antibacterial activity
ofLactobacillus sakeisolated from meat. Appl Environ
Microbiol 55: 19011906. [Medline]18. Parente E, Grieco S, Crudele MA. 2001. Phenotypic
diversity of lactic acid bacteria isolated from fermented
sausages produced in Basilicata (Southern Italy). J
Appl Microbiol 90: 943952. [Medline] [CrossRef]
19. Rodas AM, Ferrer S, Pardo I. 2003. 16S-ARDRA, atool for identication of lactic acid bacteria isolatedfrom grape must and wine. Syst Appl Microbiol 26:412422. [Medline] [CrossRef]
20. Edwards U, Rogall T, Blocker H, Emde M, BottgerEC. 1989. Isolation and direct complete nucleotidedetermination of entire genes. Characterization of a
gene coding for 16S ribosomal RNA. Nucleic Acids
Res 17: 78437853. [Medline]21. Saitou N, Nei M. 1987. The neighbor-joining method:
a new method for reconstructing phylogenetic trees.Mol Biol Evol 4: 406425. [Medline]
22. Axelsson L. 2004. Lactic acid bacteria: classifcation
and physiology. In: Lactic acid bacteria microbiologicaland functional aspects, Salminen S, von Wright A, and
Ouwehand A. (Eds), Marcel Dekker, Inc. New York. pp.
19-85.
23. Sneath A, Mair SH, Sharp ME, Holt GR. (Eds) 1986.Bergeys Manual of Systematic Bacteriology. Williams
& Wilkins, Baltimore.24. Dworkin M, Falkow S, Rosenberg E, Schleifer KH,
Stackebrandt E., editors. 2006. The Prokaryotes: aHandbook on the Biology of Bacteria. 3rd Edition, Vol.4, Springer, 1127p.
25. Stirling AC, Whittenburg R. 1963. Sources of the lacticacid bacteria occurring in silage. J Appl Bacteriol 26:
8690. [CrossRef]26. Weise F. 1973. Saurebildungsvennogen und Okonomiedes Zuckerverbrauches von Lactobazillen aus Garfutter.Landbauforschung Volkenrode 23: 7177.
27. Woolford MK. 1975. Microbiological screening ofthe straight chain fatty acids (CC) as potential silage
additives. J Sci Food Agric 26: 219228. [Medline][CrossRef]
28. Nilsson PE, Nilsson PE. 1956. Some characteristicsof silage microora. Arch Mikrobiol 24: 396411.[Medline] [CrossRef]
29. Mundt JO, Hammer JL. 1968. Lactobacilli on plants.Appl Microbiol 16: 13261330. [Medline]
30. Mundt JO, Beatrie WG, Wieland FR. 1969. Pediococciresiding on plants. J Bacteriol 98: 938942. [Medline]31. Helander IM, von Wright A, Mattila-Sandholm T.
1997. Potential of lactic acid bacteria and novelantimicrobials against gram-negative bacteria. TrendsFood Sci Technol 8: 146150. [CrossRef]
32. Daeschel MA, Andersson RE, Fleming HR. 1987.Microbial ecology of fermenting plant materials.
FEMS Microbiol Rev 46: 357367. [CrossRef]33. Trias R, Baeras L, Badosa E, Montesinos E. 2008.
Lactic acid bacteria from fresh fruit and vegetables
as biocontrol agents of phytopathogenic bacteria and
-
7/27/2019 Hani Belhadj Et Al. 2014 (BMFH)
13/13
POLLEN RESIDING ANTAGONISTIC LACTIC ACID BACTERIA 23
fungi. Int Microbiol 11: 231236. [Medline]
34. Con AH, Gokalp HY, Kaya M. 2001. Antagonisticeffect on Listeria monocytogenes and L. innocua of
a bacteriocin-like metabolite produced by lactic acidbacteria isolated from sucuk. Meat Sci 59: 437441.
[Medline] [CrossRef]35. Mataragas M, Drosinos EH, Metaxopoulos J. 2003.Antagonistic activity of lactic acid bacteria against
Listeria monocytogenes in sliced cooked cured porkshoulder stored under vacuum or modied atmosphereat 4 2C. Food Microbiol 20: 259265. [CrossRef]
36. Sandine WE. 1979. Role of Lactobacillus in theintestinal tract. J Food Prot 42: 259262.
37. Ashena M. 1991. Growth ofListeria monocytogenesin fermenting tempeh made of various beans and its
inhibition byLactobacillus plantarum. Food Microbiol
8: 303310. [CrossRef]38. Harris LJ, Fleming HP, Klaenhammer TR. 1992.
Characterization of two nisin producing Lactococcuslactis subsp. lactis strains isolated from commercialsauerkraut fermentation. Appl Environ Microbiol 58:14771483. [Medline]
39. Chateau N, Castellanos I, Deschamps AM. 1993.
Distribution of pathogen inhibition in theLactobacillus
isolates of a commercial probiotic consortium. J Appl
Bacteriol 74: 3640. [Medline] [CrossRef]40. Drago L, Gismondo MR, Lombardi A, de Hae C,
Gozzini L. 1997. Inhibition of in vitro growth ofenteropathogens by new Lactobacillus isolates ofhuman intestinal origin. FEMS Microbiol Lett 153:455463. [Medline] [CrossRef]
41. Stiles ME, Holzapfel W. 1997. Lactic acid bacteria offoods and their current taxonomy. Int J Food Microbiol36: 129. [Medline] [CrossRef]
42. Batish VK, Roy U, Lal R, Grover S. 1997. Antifungal
attributes of lactic acid bacteria a review. Crit RevBiotechnol 17: 209225. [Medline] [CrossRef]
43. Sathe SJ, Nawani NN, Dhakephalkar PK, Kapadnis BP.2007. Antifungal lactic acid bacteria with potential toprolong shelf-life of fresh vegetables. J Appl Microbiol
103: 26222628. [Medline] [CrossRef]44. Siezen RJ, Tzeneva VA, Castioni A, Wels M, PhanHTK, Rademaker JLW, Starrenburg MJC, KleerebezemM, Molenaar D, Van-Hylckama-Vlieg JET. 2010.Phenotypic and genomic diversity of Lactobacillus
plantarumstrains isolated from various environmental
niches. Environ Microbiol 12: 758773. [Medline][CrossRef]
45. Siezen RJ, Renckens B, van Swam I, Peters S, vanKranenburg R, Kleerebezem M, de Vos WM. 2005.Complete sequences of four plasmids of Lactococcus
lactissubsp. cremorisSK11 reveal extensive adaptationto the dairy environment. Appl Environ Microbiol 71:
83718382. [Medline] [CrossRef]46. Cagno RD, Minervini G, Sgarbi E, Lazzi C, BerniniV, Neviani E, Gobbetti M. 2010. Plantaricin MGactive against Gram-negative bacteria produced byLactobacillus plantarum KLDS1.0391 isolated fromJiaoke, a traditional fermented cream from China.Food Contr 21: 8996. [CrossRef]
47. Buckenhskes HJ. 1997. Fermented vegetables, In:Food Microbiology: Fundamentals and Frontiers.
Doyle PD, Beuchat LR, and Montville TJ, (Eds), 2nded. ASM Press, Washington, DC, 595609 pp.
48. Tanganurat W, Quinquis B, LeelawatcharamasV, Bolotin A. 2009. Genotypic and phenotypic
characterization of Lactobacillus plantarum strainsisolated from Thai fermented fruits and vegetables. J
Basic Microbiol 49: 377385. [Medline] [CrossRef]